DEHT is a suitable plasticizer option for phthalate-free storage of irradiated red blood cells.

BACKGROUND AND OBJECTIVES: Due to increasing concerns about possible endocrine-disrupting properties, the use of the plasticizer di(2-ethylhexyl) phthalate (DEHP) will be banned in future blood storage. Di(2-ethylhexyl) terephthalate (DEHT) provides sufficient red blood cell (RBC) quality during conventional blood bank storage. It is important that a new plasticizer also maintains acceptable quality during exposure to high cell stress, such as irradiation, which is commonly used to prevent graft-versus-host disease. MATERIALS AND METHODS: A total of 59 RBC units were collected and processed in polyvinyl chloride (PVC)-DEHT or PVC-DEHP blood bags combined with either saline-adenine-glucose-mannitol (SAGM) or phosphate-adenine-glucose-guanosine-saline-mannitol (PAGGSM) additive solution. All units were X-ray irradiated on day 2 post-collection. Sampling for assessment of parameters of storage lesion was performed on day 2 pre-irradiation and day 14 and 28 post-irradiation. RESULTS: Though irradiation increased cell stress, DEHT/PAGGSM and current common European preference DEHP/SAGM were equally affected up to 14 days post-irradiation for all measured parameters. At day 28, haemolysis and microvesicle count were slightly increased in DEHT, whereas extracellular potassium ions, glucose, lactate, pH, mean corpuscular volume and microvesicle phosphatidylserine remained unaffected by plasticizer choice throughout storage. No individual unit exceeded 0.8% haemolysis, not even in DEHT/SAGM, the combination overall most affected by irradiation. Of the four combinations, membrane stability was least impacted in DEHP/PAGGSM. CONCLUSION: We demonstrate that DEHT is a suitable plasticizer for storage of RBCs after X-ray irradiation cell stress. This strengthens the option of DEHT as a viable non-phthalate substitute for DEHP.

Non-phthalate plasticizer DEHT preserves adequate blood component quality during storage in PVC blood bags.

BACKGROUND AND OBJECTIVES: Commercial blood bags are predominantly made of polyvinyl chloride (PVC) plasticized with di(2-ethylhexyl) phthalate (DEHP). DEHP is favourable for storage of red blood cells (RBC). Historically, removal of DEHP from blood bags has been linked to unacceptable haemolysis levels. Oncoming regulatory restrictions for DEHP due to toxicity concerns increase the urgency to replace DEHP without compromising RBC quality. Di(2-ethylhexyl) terephthalate (DEHT) is one suggested substitute. The aim of this study was to compare PVC-DEHT to PVC-DEHP blood bags using additive solutions saline-adenine-glucose-mannitol (SAGM) and phosphate-adenine-glucose-guanosine-saline-mannitol (PAGGSM), to determine whether DEHT can maintain acceptable component quality. MATERIALS AND METHODS: RBC concentrates (N = 64), platelet concentrates (N = 16) and fresh frozen plasma (N = 32) were produced from whole blood collected into either DEHT or DEHP plasticized systems. Using a pool-and-split study design, pairs of identical RBC content were created within each plasticizer arm and assigned either SAGM or PAGGSM. Storage effects were assessed weekly for 49 days (RBC), 7 days (platelets) and before/after freezing (plasma). RESULTS: Though haemolysis was slightly higher in DEHT, all study arms remained below half of the European limit 0·8%. K+ was lower in DEHT than in DEHP independent of additive solution. The metabolic parameters were not influenced by choice of plasticizer. Platelet activation/metabolism and plasma content were similarly preserved. CONCLUSION: Our study demonstrates that the plasticizer DEHT provides adequate blood component quality. We propose DEHT as a strong future candidate for replacement of DEHP in blood bags.

A novel protocol for cryopreservation of paediatric red blood cell units allows increased availability of rare blood types.

BACKGROUND AND OBJECTIVES: There is a growing concern for shortage in future blood supply, caused by a predicted decrease in eligible blood donors and simultaneous increase in recipients. Cryopreservation of split red blood cell units could increase stock supply by reducing waste of rare blood. This would be particularly useful in paediatric care where very small volumes often are transfused. The aim of this study was to develop a cryopreservation protocol for split units using the closed-system automated cell processor ACP215, as such protocols are currently missing. MATERIALS AND METHODS: Using a pool-and-split design, red blood cell units (N = 8) were glycerolized and frozen, either as standard volume reference units, or further divided into three smaller split units each. After thawing/deglycerolization, the supernatant of the smaller splits was reduced by additional centrifugation, and new SAGM was added to 60% haematocrit. The units were analysed for storage lesion effects up to ten days post-thawing. RESULTS: Haemolysis and extracellular potassium ion levels were lower in the split units than in the whole units from day three onwards. The metabolic parameters pH, ATP, glucose and lactate were also lower, though likely caused by lower additive solution pH rather than storage. CONCLUSION: Split units of red blood cells can be successfully cryopreserved using the ACP215. In addition to favourably low haemolysis and potassium, they also have higher haematocrit than corresponding whole units and enable involvement of fewer donors at repeated transfusions. These characteristics are all desirable features in paediatric care.